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Medical Research Archives Universal estimation of cardiovascular risk Universal estimation of cardiovascular risk in multi-risk constellations - a “relativity theory” for global risk calculation Jörg Piper Author: Piper, Jorg, Prof. Dr. Senior Consultant Department for Internal Medicine and Cardiovascular Medicine Clinic Meduna Clara-Viebig road 4 D-56864 Bad Bertrich Germany Email: [email protected], [email protected] Phone: +49-(0)2674-1823184 Fax: +49-(0)2674-1823182 Conflicts of interest: None declared. DOI:http://dx.doi.org/10.18 103/mra.v3i3.475 Abstract According to various published studies, at least 26 cardiovascular risk factors can contribute to the individual cardiovascular risk. For all of these risk factors quantitative risk multipliers are known which can be systematically derived from various epidemiological findings. On the other hand, only a few risk factors are considered by the risk scores established (FRAMINGHAM, PROCAM, ESC and HEART score, for instance). Thus, a relevant proportion of patients affected with myocardial infarction or other cardiovascular events do not belong to a high risk group according to these scores. Thus, alternative tools for universal risk calculation are desirable to improve the significance and sensitivity of such estimations. Based on “traditional“ risk factors considered by the scores mentioned, mathematical analyses were carried out to describe coincidences of various risk factors with regard to the resulting total risk. Their quantitative synergism and relativity can be mathematically described by a specific hyperbolic tangent function derived from the PROCAM score. By other formulas PROCAM risk calculated in this way can be transformed into corresponding FRAMINGHAM and ESC risk which are targeted at other critical end points. We consider that the special interaction of risk factors described in our mathematical models can be regarded as a general law of nature so that our formulas could be used for universal risk estimations in all risk constellations imaginable, even when multiple risk factors are coincident. Key words: Risk factors, interaction, estimation, calculation, score, Framingham, PROCAM, ESC, mathematical models, multirisk constellations, cardiovascular event, myocardial infarction, cardiovascular death 1 Medical Research Archives Universal estimation of cardiovascular risk 1. Introduction Several risk scores are established for calculating cardiovascular risk. FRAMINGHAM [23] PROCAM [3, 5, 20] and ESC score [10] are most commonly used. Some more risk scores have been derived from these scores. Thus, for instance, the HEART score [12] is a derivate from the ESC score, and the AGLA score [33] is derived from the PROCAM score. All of these risk scores are only based on a few risk factors. Several other risk factors detected as additional relevant determinants for cardiovascular risk are not considered by these scores. Moreover, some risk factors are qualitatively considered (“yes” or “no”, “existing” or “not existing”), although they modulate the cardiovascular risk quantitatively. Thus, for instance, risk associated with smoking is determined by the number of cigarettes smoked and the cardiovascular risk associated with diabetes mellitus is strongly influenced by the individual HbA1c level. Nevertheless, smoking and diabetes mellitus (so far considered) are managed as qualitative determinants by the risk scores established. Moreover, these scores are different with regard to the risk factors considered. FRAMINGHAM score: age, gender, smoking (“yes”/”no”), diabetes mellitus (“yes”/”no”), familiar clustering, systolic blood pressure, lipid levels (HDL, LDL, triglycerides) PROCAM score (“health check”): age, gender, smoking (“yes”/”no”), diabetes mellitus (“yes”/”no”), systolic and diastolic blood pressure, lipid levels (LDL, HDL, triglycerides) ESC score: age, gender, smoking (“yes”/”no”), total cholesterol, systolic blood pressure. On the other hand, we could learn from the INTERHEART study [40] that cardiovascular risk is determined by much more risk factors than taken into account by these scores. At least 26 risk factors can contribute to cardiovascular risk. This background corresponds to the fact that circa 40 - 50 percent of patients with myocardial infarction belong to low or moderate risk groups according to usual risk scores mentioned. Another problem arises from multi-risk constellations. In clinical practice global risk estimations are often made by use of a simple “country saying”: numerical risk associated with defined single risk factors can be multiplied to a resulting global risk when different risk factors are coincident. Example: When Risk factor “a” leads to reduplication and risk factor “b” to triplication of cardiovascular risk, the global risk resulting from a coincidence of both factors “a” and “b” will be sextupled (2 x 3 = 6). By use of the risk scores mentioned, however, cardiovascular risk is calculated in percent. Thus, multiplying of percent values will lead to irrational results, especially when the limit of 100 percent is exceeded. In multi-risk constellations the dominance of a singular risk factor will be successively lowered the more other, concurrent risk factors are present. This phenomenon (“relativity of a risk factor”) was recently evaluated with regard to hypertension [7]. Lastly, different risk scores are focused on different “end points”. The FRAMINGHAM score is targeted on all events associated with coronary heart disease (angina pectoris, myocardial infarction and myocardial death). The PROCAM score is a morbidity score focused at myocardial infarction. The ESC score, however, is a mortality score, calculating the risk for cardiovascular death. In view of these problems and limitations this paper presents a new universal 2 Copyright 2016 KEI Journals. All rights reserved Medical Research Archives Universal estimation of cardiovascular risk algorithm describing coincidences and relativities of risk factors and risk scores. It can be used for risk estimation in each sort of cardiovascular risk constellation. In difference from conventional risk scores quantitative factors such as smoking or diabetes mellitus are considered quantitatively as far as possible. Thus, the mathematical models presented can particularly be used for estimation of cardiovascular risk resulting from multirisk constellations including all risk factors known nowadays. Moreover, risk levels can be converted from one risk score to the other so that mortality and morbidity can be simultaneously estimated The models described may be regarded as a first step to a universally applicable “relativity-theory” of risk factors and risk scores, especially in multi-risk constellations. 2. Materials and methods were multiplied by each other and compared with the score-based results. By this means effects of single risk factors and their coincidence could be mathematically investigated. Moreover, quantitative risk levels calculated with different scores were used for developing conversion formula so that PROCAM risk can be converted into FRAMINGHAM risk and ESC risk. By intensive investigation of several published original studies and secondary sources commenting their results, quantitative aspects of all risk factors and corresponding cardiovascular risk were systematically compiled. Various “model patients” affected with several coincident risk factors were “virtually” created representing low, moderate and high risk constellations. For each risk constellation, the resulting risk was first calculated by use of the PROCAM, FRAMINGHAM and ESC score. In this way, comparative risk estimations could be carried out with regard to different scores. In a second step, well known single risk levels obtained from various studies and secondary sources The following traditionally accepted risk constellations and ranges were used in “model patients” for elaborating the mathematical tools and their adjustment to the PROCAM, FRAMINGHAM and ESC score: age, blood pressure, lipid levels, smoking, diabetes mellitus and familial clustering; further details are compiled in the text box. Risk factors and risk ranges used for mathematical calculations: - Age: 40 – 60 years - Blood pressure: 130 – 180 mmHg systolic, 80 – 95 mmHg diastolic - Total cholesterol: 6,4 – 9,0 mmol/l - LDL-cholesterol: 3,8 – 5,2 mmol/l - HDL-cholesterol: 0,7 – 1,4 mmol/l - Triglycerides: 1,7 – 2,9 mmol/l - Optional additional risks: smoking, diabetes mellitus, familial clustering. Based on these risk factors and risk ranges, several “model cases” were created with various combinations of the risk factors mentioned above. For all of these cases comparative risk calculations were carried out, using the PROCAM, FRAMINGHAM and ESC score. In separate steps, the basal risk associated with age (see section “Results”, Table 1 [3, 20]) was multiplied with risk multipliers investigated (see section “Results”, Table 2). Thus all risk levels calculated by use of the scores could 3 Copyright 2016 KEI Journals. All rights reserved Medical Research Archives Universal estimation of cardiovascular risk be compared with corresponding risk levels resulting from multiplying single risk values according to the Tables 1 and 2. Based on these comparative calculations, mathematical models were elaborated to estimate the resulting total risk also in cases with a lot of coincident risk factors. Moreover, algorithms were developed to convert each sort of risk constellation from one score to the other (PROCAM to FRAMINGHAM, PROCAM to ESC). its correlation to hypertension - Type A- person because of the correlation to psychosocial stress. According to the PROCAM score patients were divided into three categories of individual risk: Low risk (< 10%), moderate risk (10% - 20%), high risk (> 20%). 3. Results The following risk factors were not separately considered, because they “overlap” with other risk factors: - Apolipoprotein A1 and B because of their correlation to the HDL- and LDLcholesterol - Left ventricular hypertrophy because of 3.1. Investigation of risk factors and risk multipliers These levels of basal risk associated with age were calculated for healthy male persons who are not affected with relevant risk factors (LDL-cholesterol 3.1 mmol/l, HDL-Cholesterol 1.4 mmol/l, triglycerides 1.7 mmol/l, systolic blood pressure 130 mmHg). For women, corresponding risk levels are lower (circa a quarter) – according to suggestions of the PROCAM study group. This basal risk determined by age is relevant for each individual regardless of whether affected with other risk factors or not. As defined by the PROCAM algorithm, the risk values compiled in Table 1 (in percent) are related to the manifestation of a fatal or non fatal myocardial infarction calculated for a period of the following 10 years. With regard to the age, corresponding risk levels remain “low” up to the “cut-off” of 65 years. By use of the PROCAM score the “physiological” cardiovascular risk depending on age was estimated as follows (Table 1): Based on literature quantitative risk multipliers were complied for “traditional” risk factors generally accepted and evaluated already decades ago (Table 2) and for several “new” risk factors being in the current focus of interest (Table 3). According to the findings of the INTERHEART study three protective “bonus factors” are relevant for reducing cardiovascular risk (Table 4). Moreover, some fixed numeric multipliers for defined risks were published by several authors 4 Copyright 2016 KEI Journals. All rights reserved Medical Research Archives Universal estimation of cardiovascular risk (Table 5). These multipliers can be used for risk estimations in general, leading to average risk levels without regarding individual quantities. Lastly, the grade of average coronary calcification can be evaluated by high resolution computer tomography and quantified by the AGATSON score (Table 6, [1, 2, 25]). 5 Copyright 2016 KEI Journals. All rights reserved Medical Research Archives Universal estimation of cardiovascular risk 6 Copyright 2016 KEI Journals. All rights reserved Medical Research Archives Universal estimation of cardiovascular risk 3.2. Mathematical model for global risk calculation (according to PROCAM score) When the “traditional” risk values presented in the Tables 1 and 2 are multiplied by each other in various “virtual” risk constellations as described above (Table 7), the results of multiplications are approximately identical with the corresponding risk levels calculated with the PROCAM score, as long as the product is lower than 30 %. In other cases, when multiplications of single risk levels exceed 30 %, the product “x” can be processed by the following hyperbolic tangent function (Fig. 1) to estimate a realistic total risk “f(x)” according to the PROCAM score: f(x) = 100 tanh (0,008x) [%]. 7 Copyright 2016 KEI Journals. All rights reserved Medical Research Archives Universal estimation of cardiovascular risk Fig. 1: Regression graph for calculation of total risk in constellations characterized by multiple coincident risk factors X-Axis: products of single risk multiplications Y-Axis: resulting total risk, adjusted to the PROCAM score The formula describes synergism and relativity of multiple coincident risk factors based on the PROCAM score; it is derived from the regression graph shown in Fig. 1. It defines the risk for myocardial infarction based on a period of 10 years, calculated for male individuals aged from 30-65 years. The corresponding risk levels for women are circa 0.25-fold lower according to the suggestions of the PROCAM Study group. The higher is the number of risk factors or the product of risk factor multiplications, the lower is the contribution of each single risk factor to the resulting total risk. 3.3. Mathematical transformation of PROCAM risk into FRAMINGHAM risk PROCAM risk levels can be transformed to FRAMINGHAM-risk levels to estimate higher risk levels for all manifestations of coronary heart disease. Conversing factors mathematically derived are presented in Table 8. Based on the PROCAM risk value “P”, the corresponding FRAMINGHAM risk level “FR” can be approximately calculated by a conversion factor “F”, the PROCAM risk value “P” has to be multiplied with: The exponent “n” ranges from 0.5 to 0.8. The FRAMINGHAM risk range corresponding with a well defined PROCAM risk can be described and estimated based on the graphs shown in Fig. 2 (x-axis: PROCAM risk, y-axis: conversing factor): 8 Copyright 2016 KEI Journals. All rights reserved Medical Research Archives Universal estimation of cardiovascular risk 9 Copyright 2016 KEI Journals. All rights reserved Medical Research Archives Universal estimation of cardiovascular risk 10 Copyright 2016 KEI Journals. All rights reserved Medical Research Archives Universal estimation of cardiovascular risk Fig. 2: Conversing factors for transforming PROCAM risk into FRAMINGJAM risk. X-Axis: PROCAM-risks in percent Y-Axis: conversing factors (multipliers for estimation of corresponding FRAMINGHAM-risk levels Graph A: minimum conversing factors Graph B: maximum conversing factors Graph A (exponent n = 0.8) and graph B (exponent n = 0.5) correspond with the minimal (A) and maximal (B) conversing factors; both graphs are suitable for estimating the approximate range of FRAMINGHAM risk levels corresponding to PROCAM risk. In low risk constellations according to PROCAM, the average corresponding FRAMIMGHAM-risk is about 3.5-fold higher, in moderate risk constellations about 2.5-fold, and in high risk constellations about 2.0-fold or lower. When PROCAM risk values are higher than 30 %, there remain no relevant differences to the corresponding FRAMINGHAM risk levels; this finding should be noticed in practice. 11 Copyright 2016 KEI Journals. All rights reserved Medical Research Archives Universal estimation of cardiovascular risk 3.4. Mathematical transformation of PROCAM risk into ESC risk Calculated PROCAM risk can be transformed into ESC risk to estimate the corresponding lower risk for cardiovascular death. These calculations can be separately carried out for so-called “low risk” and “high risk” countries. Some conversion factors used for multiplying PROCAM risk levels in order to obtain corresponding ESC risk levels are compiled in Table 9. 12 Copyright 2016 KEI Journals. All rights reserved Medical Research Archives Universal estimation of cardiovascular risk Fig. 3: Regression graphs for converting PROCAM risk into ESC risk, calculations for “high risk countries” (top) and “low risk countrie”s (bottom). X-Axis: PROCAM-risk Y-Axis: Corresponding risk according to the ESC score Separate graphs for maximum (1), medium/average (2) and minimum (3) risk levels 13 Copyright 2016 KEI Journals. All rights reserved Medical Research Archives Universal estimation of cardiovascular risk As shown in Fig. 3, a calculated PROCAM risk value “P” can be approximately converted to a corresponding ESC score risk level “E” by linear functions: For low risk countries: - m = 0.1136 (minimum factor) - m = 0.2045 (average factor) - m = 0.2955 (maximum factor). E = mxP The proportionality factor “m” is different for low and high risk countries. For high risk countries: - m = 0.2826 (minimum factor) - m = 0.3846 (average factor) - m = 0.5652 (maximum factor). 4. Implications for practical use 4.1. General advices for practical use When risk estimations are carried out using the Tables 1-5, some logical aspects should be taken into account in order to avoid overestimation (see text box below). 4.2. Further hints for practical use Firstly risk can be calculated on the basis of age, increased lipid levels and hypertension. These calculations can be carried out by multiplying the risk values compiled in the presented tables or by using the established risk scores including existing computer-based programs. In cases of smoking and diabetes established scores can be used when calculations based on constant or fixed risk values seem to be adequate. For more differentiated calculations regarding individual blood levels of HbA1c or the number of smoked cigarettes the tabular data should be preferred. Additional risks resulting from obesity or increased abdominal fat deposition can be In high risk countries the risk levels for cardiovascular death are approximately 0.3 – 0.5-fold lower, in low risk-countries nearly 0.1 – 0.3-fold lower than the corresponding risk levels for myocardial infarction calculated by the PROCAM algorithm. estimated by using the values listed in the tables. Moreover, risks resulting from familial disposition can be calculated using the PROCAM-algorithm or the fixed multipliers according to the tables. In this way, all effects of “traditional” risk factors can be evaluated. Influences of “newer” risk factors can be calculated based on specific multipliers, too. These factors should be multiplied with each other as described. Thus, further individuals with significant risk can be recognized even when not be identified by the conventional risk scores. When products of risk factor multiplications exceed 30%, the regression graph and/or the corresponding hyperbolic tangent function can be used to estimate realistic total risk levels adjusted to the PROCAM score (see Fig. 1 and Table 6). PROCAM risk calculated in the ways described can be transformed into corresponding risk levels based on the FRAMINGHAM and/or ESC score based on conversing factors and linear functions described. These transformations can be 14 Copyright 2016 KEI Journals. All rights reserved Medical Research Archives Universal estimation of cardiovascular risk carried out in all potential risk factor constellations, also in cases with multiple newer risk factors. Fixed published multipliers can also be used for general risk calculations based on average risk levels and carried out without regarding individual quantities. All in all, many existing risk constellations can be calculated in the ways described which are not taken into account by the risk scores established. General aspects which should be noted for risk calculation: (1) For calculation of the cholesterol-based risk: total cholesterol or LD-cholesterol and HDL-cholesterol or Cholesterol-HDL-ratio should be used. (2) For calculation of risk associated with hypertension: risk multipliers for systolic or diastolic blood pressure should be used. (3) For calculation of risk associated with abdominal fat deposition: WHR or waist circumference should be used. (4) For calculation of risk associated with obesity: multipliers for BMI, WHR or waist circumference should be used. (5) For calculation of risk associated with lipoproteine (a): lipoproteine (a) should only be considered when the LDL level exceeds 3.37 mmol/l as recommended by the PROCAM study group. 5. Discussion We could learn from several studies, especially the INTERHEART Study, that myocardial infarctions result from a cluster of various risk factors - and from much more risk factors than considered by the established scores. Thus, these scores, even when based on prospective studies, are not suitable for calculating the individual cardiovascular risk in all cases affected with increased risk. Circa 50 % of all patients with myocardial infarction belong to populations with a moderate or low risk according to usual scores. In such cases other risk factors are dominant, which are not taken into account by standard scores. The mathematical models presented can be used to calculate individual cardiovascular risk in a more universal manner using specific numeric modulators considering all relevant “traditional” and “new” risk factors. These methods were evaluated based on traditional risk constellations which are considered by the established risk scores based on the results of prospective studies. Nevertheless, the formulas and regression graphs developed can also be used for estimation of risk induced by “new” risk factors investigated by case–control studies. Of course, mathematical models based on prospective and case-control studies may be regarded as problematic as both types of studies have their characteristic potential bias, especially selection bias (prospective studies) and memory bias (case-control study). On the other hand, there is no other way at the present to establish mathematical models for global risk estimations with regard to all risk factors currently known, because only a few risk factors have yet been investigated by prospective studies. 15 Copyright 2016 KEI Journals. All rights reserved Medical Research Archives Universal estimation of cardiovascular risk Moreover, it could be considered that the results of the case-controlling INTERHEART-study are not drastically different from the corresponding results of prospective studies, when risk factors are taken into account investigated in both ways by prospective and case control studies. Using the tables, graphs and formulas presented, physicians can quickly estimate the total cardiovascular risk of their individual patients based on clinical and laboratory diagnostic parameters including “new” risk factors. Moreover, prognostic rankings for all conceivable risk constellations can be made. Global risk estimations of this sort can be helpful for strategies and individual decisions in cardiovascular prevention aimed at those individuals who might benefit from prevention programs in a significant manner improving their long time-prognosis. When total risk levels are comparatively estimated based on PROCAM, FRAMINGHAM and ESC score, separate risk estimations for all manifestations of coronary heart disease (FRAMINGHAM), myocardial infarction (PROCAM) and cardiovascular death (ESC score) can be carried out. By these means, the prognostic weights of various risk constellations can be evaluated and compared with special regard to their specific potential complications. Moreover, the scores mentioned can be compared with each other on a mathematical basis. The relations between the various risk scores mathematically analyzed are congruent with patho-physiological and epidemiological facts. Based on a defined period, e.g. 10 years, in each population the number of individuals with all clinical manifestations of coronary heart disease (CHD) is higher than the number of patients with myocardial infarctions, and the number of patients with myocardial infarctions is higher than the number of fatal cardiovascular events. Moreover, the higher is the total individual risk level, the lower are the numeric differences of all CHD manifestations, myocardial infarctions and cases with cardiovascular death arising in a course of several years. Therefore, different results of risk calculations dependent on different risk scores should not be regarded as inconsistent. It is desirable that new prospective studies are aimed to “new” risk factors mentioned above, so that the established scores might be expanded including all relevant “new” modulators. In this way, the relevance and predictive “sensitivity” of these scores might be improved, quantitative effects of “new” risk factors derived from casecontrol studies at the present could be corrected in the future, if necessary, and the mathematical models presented here could be checked by multivariate analysis. Thus, epidemiological research might confirm in the future that the mathematical algorithms developed describe in-fact a law of nature which is valid in all cardiovascular risk factors and their combinations. A complementary way for risk estimation based on morphological findings is represented by the AGATSTON score [1, 2, 25]. Coronary calcification indices correspond with cardiovascular risk and can be used as additional risk indicators, especially in high risk constellations (Table 6). 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